Probing new forces with nuclear-clock quintessometers

Cédric Delaunay; Seung J. Lee; Roee Ozeri; Gilad Perez; Wolfram Ratzinger; Bingrong Yu

doi:10.48550/arXiv.2503.02932

Probing new forces with nuclear-clock quintessometers

Cédric Delaunay, Seung J. Lee, Roee Ozeri, Gilad Perez, Wolfram Ratzinger, Bingrong Yu

Weizmann Institute of Science

Research output: Contribution to journal › Article

Abstract

Clocks based on nuclear isomer transitions promise exceptional stability and precision. The low transition energy of the Thorium-229 isomer makes it an ideal candidate, as it may be excited by a vacuum-ultraviolet laser and is highly sensitive to subtle interactions. This enables the development of powerful tools for probing new forces, which we call quintessometers. In this work, we demonstrate the potential of nuclear clocks, particularly solid-state variants, to surpass existing limits on scalar field couplings, exceeding the sensitivity of current fifth-force searches at submicron distances and significantly improving equivalence-principle tests at kilometer scales and beyond. Additionally, we highlight the capability of transportable nuclear clocks to detect scalar interactions at distances beyond 10 km, complementing space-based missions.

Original language	English
Journal	arxiv.org
DOIs	https://doi.org/10.48550/arXiv.2503.02932
State	In preparation - 4 Mar 2025

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title = "Probing new forces with nuclear-clock quintessometers",

abstract = "Clocks based on nuclear isomer transitions promise exceptional stability and precision. The low transition energy of the Thorium-229 isomer makes it an ideal candidate, as it may be excited by a vacuum-ultraviolet laser and is highly sensitive to subtle interactions. This enables the development of powerful tools for probing new forces, which we call quintessometers. In this work, we demonstrate the potential of nuclear clocks, particularly solid-state variants, to surpass existing limits on scalar field couplings, exceeding the sensitivity of current fifth-force searches at submicron distances and significantly improving equivalence-principle tests at kilometer scales and beyond. Additionally, we highlight the capability of transportable nuclear clocks to detect scalar interactions at distances beyond 10 km, complementing space-based missions.",

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AU - Delaunay, Cédric

AU - Lee, Seung J.

AU - Ozeri, Roee

AU - Perez, Gilad

AU - Ratzinger, Wolfram

AU - Yu, Bingrong

PY - 2025/3/4

Y1 - 2025/3/4

N2 - Clocks based on nuclear isomer transitions promise exceptional stability and precision. The low transition energy of the Thorium-229 isomer makes it an ideal candidate, as it may be excited by a vacuum-ultraviolet laser and is highly sensitive to subtle interactions. This enables the development of powerful tools for probing new forces, which we call quintessometers. In this work, we demonstrate the potential of nuclear clocks, particularly solid-state variants, to surpass existing limits on scalar field couplings, exceeding the sensitivity of current fifth-force searches at submicron distances and significantly improving equivalence-principle tests at kilometer scales and beyond. Additionally, we highlight the capability of transportable nuclear clocks to detect scalar interactions at distances beyond 10 km, complementing space-based missions.

AB - Clocks based on nuclear isomer transitions promise exceptional stability and precision. The low transition energy of the Thorium-229 isomer makes it an ideal candidate, as it may be excited by a vacuum-ultraviolet laser and is highly sensitive to subtle interactions. This enables the development of powerful tools for probing new forces, which we call quintessometers. In this work, we demonstrate the potential of nuclear clocks, particularly solid-state variants, to surpass existing limits on scalar field couplings, exceeding the sensitivity of current fifth-force searches at submicron distances and significantly improving equivalence-principle tests at kilometer scales and beyond. Additionally, we highlight the capability of transportable nuclear clocks to detect scalar interactions at distances beyond 10 km, complementing space-based missions.

U2 - 10.48550/arXiv.2503.02932

DO - 10.48550/arXiv.2503.02932

M3 - مقالة

SN - 2331-8422

JO - arxiv.org

JF - arxiv.org

ER -

Probing new forces with nuclear-clock quintessometers

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